Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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The present invention relates to an off-shore
structure suitable for drilling for and production of
hydrocarbons. The off-shore structure is intended to
be installed at very great depths, preferably more than
200 meters. Particularly, but exclusively, the
present invention relates to a platform that is well
suited to be built in concrete. The off-shore structure
comprises a foundation or base structure, intended to
be forced down in the seabed, a cellular lower structure
or substructure that is completely submerged in its
operational position, and an upper structure extending
from the said lower structure upwards above the surface,
which may support a deck superstructure above the
surface. The lower structure comprises a centrally
located cell surrounded by at least one ring of cells.
The upper structure may be formed by extending the walls
of at least one of the cells in the lower structure.
The present invention also relates to a method for
constructing the foundation of an off-shore structure
which at its lower end is provided with a foundation
structure in the form of downward extending skirts
that are open at their lower end and closed at their
upper end, intended to be forced down into the seabed
for support of the off-shore structure.
Previous opinion has been that gravitation
platforms of the caisson type, for example the well
known Condeep platform, is unsuitable for use at depths
in excess of 200 - 250 meters. At such depths it has
so far only been suggested the use of floating
production platforms and/or truss type platforms or
the platform type as disclosed in Norwegian Patents
140,431 and 142,005. One of the reasons that the
caisson type platforms so far have been considered
unsuitable for great depths is that the forces and
dynamic motions caused by wave motion have been
considered too great for the practical application
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of such platforms at great depths. Also, this effect
would be amplified in cases where the platform is
provided with more than one column, as the effect
increases rapidly with an increase number of columns.
Furthermore, the great water pressure exeraised on the
lower portion of the platform structure will result in
the need for extremely large wall thickness in the
air fil]ed portions of the platform, with consequent
irlcrease in weight and cost.
An object of the present invention is to provide
an off-shore platform structure that will overcome
the above disadvantages, that is suitable for installation
at depths in excess of 200 - 250 meters and that can be
built in a relatively short time, say 3 - 4 years. A
further object is to provide a platform structure that
is substantially based on well tried building techniques
where dimensions to a great have been optimized.
A further object of the present invention is to
provide a foundation that works li]ce a pile foundation,
but where the foundation itself can be constructed
without the time consuming pile driving operation;
where a significant portion of the vertical forces from
the platform and/or waves will be carried by friction/
adhesion along the skirt walls, plus point loading so
that significant portions of the ver-tical load are
displaced to deeper ground layers where load carrying
strength is sufficient without a pile structure.
Still another object of the invention is to
provide a founding method and a foundation where the
need for grouting of the space bounded by the skirt
walls, the sea bed and the lower structure is fully or
partially eliminated.
According to the invention there is provided a
platform in which the lower structure is equipped with
cells where the inside diameters of the cell walls
art tangent to one another.
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According to a preferred embodiment, the upper structure
consists of at least one column that is formed by extending the walls of
the lower structure, while the cell shape is altered from a part polygonal,
part circular to an all circular cross section.
Further the walls of the lower structure may have decreasing
wall thickness in the upward direction. In addltion many portions of the
cell walls, for example walls of individual cells of the lower structure,
may, be dimensioned to not withstand significant water pressure.
The present invention further provides a structure where
water under pressure is pumped into the space between the sea bed, the skirt
walls and the lower structure after the off-shore structure is planted on
the sea bed and the skirts have penetrated the sea bed to desired depths.
The high pressure is maintained either by sealing the said space and/or by
a more or less continuous maintenance of pressure by otner means, for
example by pumping.
By carrying the vertical forces caused by the weight of the
platform and the waves by friction/adhesion along the skirt walls at the
significant heigllt, and by the loading polnts at the end plates of the
skirts, the platform will work more like a pile structure than a gravitation
plstform. The vertical load may be adjusted by varying the water ballast
in the platform. Possible setting may be compensated for by pumping water
into the space formed by the skirt walls, the sea bottom and the lower
structure and/or by reducing the water ballast in the platform.
To increase the load bearing surface of the platform in the
horizontal and/or vertical direction, it is possible to provide additional
rings of cells along the lower portion of the lower structure. Advanta-
geously the walls of the additional cells may be dimensioned to not withstand
a significant external
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water pressure.
The skirts according to the present invention may for
example have a height in excess of 30 meters, while the lower
structure may have a heiyht in excess of 150 meters. Height and
weight of the lower structure, including the skirt heights, may be
adjusted to the towing depths rather than to the effect of wave
load at the platform location.
According to another preferred embodiment, lower
portions of the lower structure may consist of walls that are not
designed to withstand higher water pressure, while the upper
portion of the lower structure is made as a high pressure unit
where the high pressure portion functions as an intermediate
bracing structure for the column cells.
The platform according to the present invention may have
one, two or more columns. The columns may be formed by one or
more cells in the first ring of cells around the central cell.
This makes possible a more flexible deck lay out.
For a more detailed description of the preferred
embodiments of the present invention is referred to the drawing
figures, wherein:
Figure 1 shows a vertical section through an off-shore
structure intended for installation at a depth of 334 meters,
viewed along the line 1-1 in figure 2;
Figure 2 shows a horizontal section viewed along the
line 2-2 in figure 1;
Figure 3 shows another embodiment of the invention;
Figures 4 to 8 show various cross sections on Figure 3;
Figure 9 shows a further embodiment of the invention;
Figures 10 to 14 show various cross sections on Figure 9;
Figure 15 shows another embodiment of the invention, and
Figures 16 and 17 show various cross sections on Figure 15.
Figure 1 shows a vertical section through a preferred
embodiment of an off-shore platform structure 1 according to the
present invention. The platform structure 1 comprises a completely
submerged lower section 2, from which extends an upper construction
4 up to above the sea surface 3, plus a foundation or base struc-
ture 5 which is forced down in the sea bed 6. The platform shown
in figure 1 is intended to
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operate at very great depths, and may for this purpose
be equipped with a deck superstructure (not shown) plus
equipment for drilling for and/or production of
hydrocarbons.
The foundation struc-ture 5 includes a plurality of
skirts 7. These may for example consist of cylindrical,
vertical tubes or of vertical walls with to a greater
or to a less degree are connected with one another.
The skirts may for example be made or concrete, and
unlike the previously used skirts, may have a consider-
able thickness, for example 45 - 70 cm. The said skirt
7 is given a sufficient vertical dimension to be forced
down in the sea bed, for example by ballasting the
platform during the installation phase, that the lower
layers in the sea bed helps carrying the platform. The
skirts 7 in the present case consist of an extension
of the walls 8 in the cells 9 in the lower section 2.
However, the thickness of the walls in the skirts 7
is less than the thickness of the walls 8 in the cells
9. As shown in figure 1, the lower structure 2 is in
addition equipped with an outer ring of cells 10.
This comprises a plurality of cells 11 which are
connected with one another in the same manner as the
inner ring of cells. In addition the outer ring of
cells 10 is connected with the inner ring of cells by
means of upper and lower plates (12, 13) plus vertical
discs (not shown) extending across the cells 11 in the
outer ring of the cells 10, radially inwards to the
outer walls of the cells 8 where these end. The outer
ring of cells 10 have a small height, and are not
dimensioned to withstand a pressure beyond that which
will arise during towing from the dock and the first
stage of casting of the lower section.
Cells 9 in the lower section 2 are at their lower
end provided with a lower spherical shell 13. The
cells 9 in the lower section which is completely
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submerged are equipped wi-th corresponding upper spherical
shells
The upper structure comprises columns 14 which
are formed by extending the walls 8 in some of the
cells 9 in the lower portion up above the sea surface
3. The columns 14 consist of a lower, tapered portion
and an upper, sylindrical portion 15. In the example
shown in figures 1 and 2 the platform is equipped with
three columns, located symmetrically around the platform's
central axis.
As shown in figures 1 and 2, the cell walls 9 in
the lower structure are very thick, that is in the
order of 1,5 - 3 meters. This means that the walls in
an area with adjacent cells will have a wall thickness
approx. the double of this.
Further, the cells 9 in the lower structure are
constructed in such a way that the inside walls,
rather than the outside walls are tangent to one
another. Accordingly, with wall thickness as in the
present case, the cells 9 along the contact surfaces
with adjacent cells will take a hexagonal shape in
cross section, while the contact surface with the
outside water will be shaped as a single curved surface.
The thickness of the walls 8 in the cells 9 decrease
toward the upper end.
Figure 3 shows another embodiment according to the
present invention. The following discussion will
describe only differences from the example shown in
figure 1.
One significant difference is that only the upper
portion 16 of the lower structure 2 is defined to
stand high pressure, while the lower portion 17 is not
dimensioned to withstand significant water pressure.
For this purpose the cells in the upper portion 16 of
the lower section 2 are equipped with upper and lower
spherical shells 13 located in the upper portion 16.
In addition the walls in this portion have thickness and reinforcement
corresponding to parts of the cell walls in the example shown in flgure 1.
According to this arrangement the upper portion 16 is intended to be
partially or fully filled with air, as are the column or columns. The
lower portion 17 of the lower structure 2, however, is intended to be
filled with water and to be in communication with the surrounding water.
Another significant difference consists of a horizontal, substantially
plane base plate 18 plus an upper plate 19 which extends through the entire
lower structure 2 except the three column cells. In addition, the cell
portion between the two horizontal plates 18, 19 is equipped with vertical
walls 20 corresponding to the outer, low ring of cells as described in
connection with the example shown in figure 1. These are also, with the
exception of the three column cells, provided in all the cells 9 in the
lower construction, as shown in figure 4.
Figure 5 shows a horizontal section viewed along the line
2-2 in figure 3, while figure 6 shows the corresponding horizontal section
through the upper high pressure portion 16 in the lower structure, viewed
along the line 1-1 in figure 3.
A final difference is that the diameter of the cylindrical
portion of the columns, and consequently the conical taper9 is different.
Figures 9 - 14 show a third embodiment of the present
invention, where the only slgnificant difference as compared to the example
of figures 4 - 8 lies in the arrangement of the ring of cells 10 around
the lower portion of the lower structure 2. According to this example
the lower portion is formed by a ring of cells 11 which is spaced from
the cells 9 in the lower structure 2. The said ring of cells is, however,
rigidly connected with the cells 9 by means of the upper and lower plates
19, 18 and the walls 21 which extend diametrically through the cells or
the lower ring of cells 11 The configuration of the disc walls is shown
in figure 10.
Figure 15 shows a third embodiment of the present invention,
equipped with only one central column 22. According to this emhodiment
the diameter of the cells 23 in the ring of cells around the central cell
24 is different from the diameter of the central cell 24.
If a construction with four columns is desired, it is
possible to use the cell configuration shown in figure 17, where the walls
of the cells marked with x may be extended upward to form columns instead
of the central cell.
To fit the lower ring of cells 10 four additional small
cells 25 are provlded.
Common to the embodiments shown is that they are all made
of concrete and are suitable for the principle of sliding forms. The
method will generally be like the building of the Condeep platforms, i.e.
the skirts and the lower portion of the lower structure are built in a
dry dock, whereupon the platform is launched and towed to the deep water
site where the remaining portion is completed. A significant difference,
however, is that the skirts are also cast by means of the principle of
sliding forms.
A further common feature Ls that the platforms are towed
out to the drilling site with the top of the lower structure extending up
above the sea surface.
Although the embodiment examples are shown with the lower
structure consisting of a central upright cell plus a surrounding ring
of cells with corresponding height and radius, it will be noted that
additional rings of cells may be provided outside the shown ring of cells.
Further, the diameter of the cells may differ from the diameter of the
central upright cell.
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If the diameter of the central cell is greater than
tha-t of the surrounding cells, the number of cells in
the surrounding ring must necessarily be greater than
what is shown on the figures and vice versa.
It shall be further noted that the invention is
not limited Jo the shown arrangement with one or three
columns, but may have any suitable number of columns
depending on the desired deck structure.